unique_ptr<T> does not allow copy construction, instead it supports move semantics. Yet, I can return a unique_ptr<T> from a function and assign the returned value to a variable.

#include <iostream>
#include <memory>

using namespace std;

unique_ptr<int> foo()
  unique_ptr<int> p( new int(10) );

  return p;                   // 1
  //return move( p );         // 2

int main()
  unique_ptr<int> p = foo();

  cout << *p << endl;
  return 0;

The code above compiles and works as intended. So how is it that line 1 doesn't invoke the copy constructor and result in compiler errors? If I had to use line 2 instead it'd make sense (using line 2 works as well, but we're not required to do so).

I know C++0x allows this exception to unique_ptr since the return value is a temporary object that will be destroyed as soon as the function exits, thus guaranteeing the uniqueness of the returned pointer. I'm curious about how this is implemented, is it special cased in the compiler or is there some other clause in the language specification that this exploits?

  • Hypothetically, if you were implementing a factory method, would you prefer 1 or 2 to return the factory's output? I presume that this would be the most common use of 1 because, with a proper factory, you actually want the ownership of the constructed thing to pass to the caller.
    – Xharlie
    Sep 15, 2015 at 11:10
  • 7
    @Xharlie ? They both pass ownership of the unique_ptr. The whole question is about 1 and 2 being two different ways of achieving the same thing.
    – Praetorian
    Sep 15, 2015 at 16:28
  • 1
    in this case, the RVO takes place in c++0x as well, the destruction of the unique_ptr object will be once which is performed after main function exits , but not when the foo exits.
    – ampawd
    Jan 19, 2019 at 14:17

7 Answers 7


is there some other clause in the language specification that this exploits?

Yes, see 12.8 §34 and §35:

When certain criteria are met, an implementation is allowed to omit the copy/move construction of a class object [...] This elision of copy/move operations, called copy elision, is permitted [...] in a return statement in a function with a class return type, when the expression is the name of a non-volatile automatic object with the same cv-unqualified type as the function return type [...]

When the criteria for elision of a copy operation are met and the object to be copied is designated by an lvalue, overload resolution to select the constructor for the copy is first performed as if the object were designated by an rvalue.

Just wanted to add one more point that returning by value should be the default choice here because a named value in the return statement in the worst case, i.e. without elisions in C++11, C++14 and C++17 is treated as an rvalue. So for example the following function compiles with the -fno-elide-constructors flag

std::unique_ptr<int> get_unique() {
  auto ptr = std::unique_ptr<int>{new int{2}}; // <- 1
  return ptr; // <- 2, moved into the to be returned unique_ptr


auto int_uptr = get_unique(); // <- 3

With the flag set on compilation there are two moves (1 and 2) happening in this function and then one move later on (3).

  • @juanchopanza Do you essentially mean that foo() is indeed also about to be destroyed (if it were not assigned to anything), just like the return value within the function, and hence it makes sense that C++ uses a move constructor when doing unique_ptr<int> p = foo();?
    – 7cows
    Jun 4, 2013 at 16:10
  • 1
    This answer says an implementation is allowed to do something... it doesn't say it must, so if this was the only relevant section, that would imply relying on this behavior isn't portable. But I don't think that's right. I am inclined to think the correct answer has more to do with the move constructor, as described in Nikola Smiljanic's and Bartosz Milewski's answer.
    – Don Hatch
    Jul 22, 2014 at 22:19
  • 7
    @DonHatch It says it's "allowed" to perform copy/move elision in those cases, but we're not talking about copy elision here. It's the second quoted paragraph that applies here, which piggy-backs on the copy elision rules, but is not copy elision itself. There is no uncertainty in the second paragraph - it's totally portable. Sep 24, 2014 at 8:34
  • 1
    This copy elision is known as RVO or Return Value Optiomization. This exists long before C++11. See en.wikipedia.org/wiki/Copy_elision#Return_value_optimization
    – jaques-sam
    Sep 13, 2018 at 12:00
  • 2
    So why do I still get the error "attempting to reference a deleted function" for my move-only type (removed copy constructor) when returning it exactly in the same way as this example?
    – jaques-sam
    May 6, 2019 at 7:58

This is in no way specific to std::unique_ptr, but applies to any class that is movable. It's guaranteed by the language rules since you are returning by value. The compiler tries to elide copies, invokes a move constructor if it can't remove copies, calls a copy constructor if it can't move, and fails to compile if it can't copy.

If you had a function that accepts std::unique_ptr as an argument you wouldn't be able to pass p to it. You would have to explicitly invoke move constructor, but in this case you shouldn't use variable p after the call to bar().

void bar(std::unique_ptr<int> p)
    // ...

int main()
    unique_ptr<int> p = foo();
    bar(p); // error, can't implicitly invoke move constructor on lvalue
    bar(std::move(p)); // OK but don't use p afterwards
    return 0;
  • 3
    @Fred - well, not really. Although p is not a temporary, the result of foo(), what's being returned, is; thus it's an rvalue and can be moved, which makes the assignment in main possible. I'd say you were wrong except that Nikola then seems to apply this rule to p itself which IS in error. Nov 30, 2010 at 18:39
  • Exactly what I wanted to say, but couldn't find the words. I've removed that part of the answer since it wasn't very clear. Nov 30, 2010 at 18:43
  • I have a question: in the original question, is there any substantial difference between Line 1 and Line 2? In my view it's the same since when constructing p in main, it only cares about the type of return type of foo, right? Sep 24, 2014 at 2:02
  • 1
    @HongxuChen In that example there's absolutely no difference, see the quote from the standard in the accepted answer. Sep 25, 2014 at 3:22
  • 1
    Actually, you can use p afterwards, as long as you assign to it. Until then, you can't try to reference the contents.
    – Alan
    Mar 15, 2017 at 14:06

unique_ptr doesn't have the traditional copy constructor. Instead it has a "move constructor" that uses rvalue references:

unique_ptr::unique_ptr(unique_ptr && src);

An rvalue reference (the double ampersand) will only bind to an rvalue. That's why you get an error when you try to pass an lvalue unique_ptr to a function. On the other hand, a value that is returned from a function is treated as an rvalue, so the move constructor is called automatically.

By the way, this will work correctly:

bar(unique_ptr<int>(new int(44));

The temporary unique_ptr here is an rvalue.

  • 9
    I think the point is more, why can p - "obviously" an lvalue - be treated as an rvalue in the return statement return p; in the definition of foo. I don't think there's any issue with the fact that the return value of the function itself can be "moved".
    – CB Bailey
    Nov 30, 2010 at 23:12
  • Does wrapping the returned value from the function in std::move mean that it will be moved twice?
    – user712850
    Apr 3, 2013 at 21:42
  • 4
    @RodrigoSalazar std::move is just a fancy cast from a lvalue reference (&) to an rvalue reference (&&). Extraneous usage of std::move on an rvalue reference will simply be a noop
    – TiMoch
    Apr 13, 2013 at 19:37

I think it's perfectly explained in item 25 of Scott Meyers' Effective Modern C++. Here's an excerpt:

The part of the Standard blessing the RVO goes on to say that if the conditions for the RVO are met, but compilers choose not to perform copy elision, the object being returned must be treated as an rvalue. In effect, the Standard requires that when the RVO is permitted, either copy elision takes place or std::move is implicitly applied to local objects being returned.

Here, RVO refers to return value optimization, and if the conditions for the RVO are met means returning the local object declared inside the function that you would expect to do the RVO, which is also nicely explained in item 25 of his book by referring to the standard (here the local object includes the temporary objects created by the return statement). The biggest take away from the excerpt is either copy elision takes place or std::move is implicitly applied to local objects being returned. Scott mentions in item 25 that std::move is implicitly applied when the compiler choose not to elide the copy and the programmer should not explicitly do so.

In your case, the code is clearly a candidate for RVO as it returns the local object p and the type of p is the same as the return type, which results in copy elision. And if the compiler chooses not to elide the copy, for whatever reason, std::move would've kicked in to line 1.

  • Is it RVO though? In The C++ Programming Language 4th Ed, p.113 shows the line return unique_ptr<X>{ new X{i} }; which I believe is pure move semantics, not RVO. If this line were changed to the following 2 lines, does that change things to be RVO? unique_ptr<X> mypX{ new X{i} }; return mypX;
    – Will
    Jul 5 at 8:21

One thing that i didn't see in other answers is To clarify another answers that there is a difference between returning std::unique_ptr that has been created within a function, and one that has been given to that function.

The example could be like this:

class Test
{int i;};
std::unique_ptr<Test> foo1()
    std::unique_ptr<Test> res(new Test);
    return res;
std::unique_ptr<Test> foo2(std::unique_ptr<Test>&& t)
    // return t;  // this will produce an error!
    return std::move(t);

auto test1=foo1();
auto test2=foo2(std::unique_ptr<Test>(new Test));
  • 1
    It is mentioned in the answer by fredoverflow - clearly highlighted "automatic object". A reference (including an rvalue reference) is not an automatic object. Jul 3, 2017 at 16:15
  • @TobySpeight Ok, sorry. I guess my code is just a clarification then.
    – v010dya
    Jul 3, 2017 at 16:33
  • Thanks for this answer! I've been trying to debug a problem caused by this for days now, and reading this answer made me realize what was wrong.
    – Nick Alger
    Apr 24, 2021 at 22:16
  • May I ask why std::move() is necessary in foo2 ?
    – Hua
    May 5 at 3:27
  • @Hua unique_ptr cannot be copied, only moved.
    – v010dya
    May 7 at 4:09

I would like to mention one case where you must use std::move() otherwise it will give an error. Case: If the return type of the function differs from the type of the local variable.

class Base { ... };
class Derived : public Base { ... };
std::unique_ptr<Base> Foo() {
     std::unique_ptr<Derived> derived(new Derived());
     return std::move(derived); //std::move() must

Reference: https://www.chromium.org/developers/smart-pointer-guidelines

  • 1
    But if I remove std::move, there is no error when compiling. The compiler will try calling the move constructor if copy constructor is not callable. So the std::move here may be redundant.
    – Jllobvemy
    Apr 18, 2022 at 10:26
  • 1
    It does not seem like the document you referenced says std::move() should be used in this case. I think it is the opposite.
    – shargors
    Feb 13 at 23:51

I know it's an old question, but I think an important and clear reference is missing here.

From https://en.cppreference.com/w/cpp/language/copy_elision :

(Since C++11) In a return statement or a throw-expression, if the compiler cannot perform copy elision but the conditions for copy elision are met or would be met, except that the source is a function parameter, the compiler will attempt to use the move constructor even if the object is designated by an lvalue; see return statement for details.

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